1. Dayan, E., and Cohen, L.G. (2011). Neuroplasticity subserving motor skill learning. Neuron 72, 443-454.
2. Karni, A., Meyer, G., Rey-Hipolito, C., Jezzard, P., Adams, M.M., Turner, R., and Ungerleider, L.G. (1998). The acquisition of skilled motor performance: fast and slow experience-driven changes in primary motor cortex. Proc Natl Acad Sci U S A 95, 861-868.
3. Muellbacher, W., Ziemann, U., Wissel, J., Dang, N., Kofler, M., Facchini, S., Boroojerdi, B., Poewe, W., and Hallett, M. (2002). Early consolidation in human primary motor cortex. Nature 415, 640-644.
4. Robertson, E.M., Press, D.Z., and Pascual-Leone, A. (2005). Off-line learning and the primary motor cortex. J Neurosci 25, 6372-6378.
5. Janacsek, K., and Nemeth, D. (2012). Predicting the future: from implicit learning to consolidation. Int J Psychophysiol 83, 213-221.
6. Doyon, J., Bellec, P., Amsel, R., Penhune, V., Monchi, O., Carrier, J., Lehericy, S., and Benali, H. (2009). Contributions of the basal ganglia and functionally related brain structures to motor learning. Behav Brain Res 199, 61-75.
7. Karni, A., Meyer, G., Jezzard, P., Adams, M.M., Turner, R., and Ungerleider, L.G. (1995). Functional MRI evidence for adult motor cortex plasticity during motor skill learning. Nature 377, 155-158.
8. Tunovic, S., Press, D.Z., and Robertson, E.M. (2014). A physiological signal that prevents motor skill improvements during consolidation. J Neurosci 34, 5302-5310.
9. Hardwick, R.M., Rottschy, C., Miall, R.C., and Eickhoff, S.B. (2013). A quantitative meta-analysis and review of motor learning in the human brain. Neuroimage 67, 283-297.
10. Albouy, G., Sterpenich, V., Balteau, E., Vandewalle, G., Desseilles, M., Dang-Vu, T., Darsaud, A., Ruby, P., Luppi, P.H., Degueldre, C., et al. (2008). Both the hippocampus and striatum are involved in consolidation of motor sequence memory. Neuron 58, 261-272.
11. Lohse, K.R., Wadden, K., Boyd, L.A., and Hodges, N.J. (2014). Motor skill acquisition across short and long time scales: a meta-analysis of neuroimaging data. Neuropsychologia 59, 130-141.
12. Doyon, J., and Benali, H. (2005). Reorganization and plasticity in the adult brain during learning of motor skills. Curr Opin Neurobiol 15, 161-167.
13. Penhune, V.B., and Steele, C.J. (2012). Parallel contributions of cerebellar, striatal and M1 mechanisms to motor sequence learning. Behav Brain Res 226, 579-591.
14. Penhune, V.B., and Doyon, J. (2002). Dynamic cortical and subcortical networks in learning and delayed recall of timed motor sequences. J Neurosci 22, 1397-1406.
15. Huang, Y.Z., Rothwell, J.C., Lu, C.S., Wang, J., Weng, Y.H., Lai, S.C., Chuang, W.L., Hung, J., and Chen, R.S. (2009). The effect of continuous theta burst stimulation over premotor cortex on circuits in primary motor cortex and spinal cord. Clin Neurophysiol 120, 796-801.
16. Huang, Y.Z., Chen, R.S., Fong, P.Y., Rothwell, J.C., Chuang, W.L., Weng, Y.H., Lin, W.Y., and Lu, C.S. (2018). Inter-cortical modulation from premotor to motor plasticity. J Physiol 596, 4207-4217.
17. Gerschlager, W., Siebner, H.R., and Rothwell, J.C. (2001). Decreased corticospinal excitability after subthreshold 1 Hz rTMS over lateral premotor cortex. Neurology 57, 449-455.
18. Munchau, A., Bloem, B.R., Irlbacher, K., Trimble, M.R., and Rothwell, J.C. (2002). Functional connectivity of human premotor and motor cortex explored with repetitive transcranial magnetic stimulation. J Neurosci 22, 554-561.
19. Ohbayashi, M., Ohki, K., and Miyashita, Y. (2003). Conversion of working memory to motor sequence in the monkey premotor cortex. Science 301, 233-236.
20. Meehan, S.K., Randhawa, B., Wessel, B., and Boyd, L.A. (2011). Implicit sequence-specific motor learning after subcortical stroke is associated with increased prefrontal brain activations: an fMRI study. Hum Brain Mapp 32, 290-303.
21. Honda, M., Deiber, M.P., Ibanez, V., Pascual-Leone, A., Zhuang, P., and Hallett, M. (1998). Dynamic cortical involvement in implicit and explicit motor sequence learning. A PET study. Brain 121 ( Pt 11), 2159-2173.
22. Boyd, L.A., and Linsdell, M.A. (2009). Excitatory repetitive transcranial magnetic stimulation to left dorsal premotor cortex enhances motor consolidation of new skills. BMC Neurosci 10, 72.
23. Meehan, S.K., Zabukovec, J.R., Dao, E., Cheung, K.L., Linsdell, M.A., and Boyd, L.A. (2013). One hertz repetitive transcranial magnetic stimulation over dorsal premotor cortex enhances offline motor memory consolidation for sequence-specific implicit learning. Eur J Neurosci 38, 3071-3079.
24. Kantak, S.S., Mummidisetty, C.K., and Stinear, J.W. (2012). Primary motor and premotor cortex in implicit sequence learning--evidence for competition between implicit and explicit human motor memory systems. Eur J Neurosci 36, 2710-2715.
25. Focke, J., Kemmet, S., Krause, V., Keitel, A., and Pollok, B. (2017). Cathodal transcranial direct current stimulation (tDCS) applied to the left premotor cortex (PMC) stabilizes a newly learned motor sequence. Behav Brain Res 316, 87-93.
26. Pollok, B., Schmitz-Justen, C., and Krause, V. (2021). Cathodal Transcranial Direct Current Stimulation (tDCS) Applied to the Left Premotor Cortex Interferes with Explicit Reproduction of a Motor Sequence. Brain Sci 11.
27. Nitsche, M.A., Jakoubkova, M., Thirugnanasambandam, N., Schmalfuss, L., Hullemann, S., Sonka, K., Paulus, W., Trenkwalder, C., and Happe, S. (2010). Contribution of the premotor cortex to consolidation of motor sequence learning in humans during sleep. J Neurophysiol 104, 2603-2614.
28. Vidoni, E.D., and Boyd, L.A. (2007). Achieving enlightenment: what do we know about the implicit learning system and its interaction with explicit knowledge? J Neurol Phys Ther 31, 145-154.
29. Robertson, E.M. (2009). From creation to consolidation: a novel framework for memory processing. PLoS Biol 7, e19.
30. Hazeltine, E., Grafton, S.T., and Ivry, R. (1997). Attention and stimulus characteristics determine the locus of motor-sequence encoding. A PET study. Brain 120 ( Pt 1), 123-140.
31. Grafton, S.T., Hazeltine, E., and Ivry, R. (1995). Functional mapping of sequence learning in normal humans. J Cogn Neurosci 7, 497-510.
32. Oldfield, R.C. (1971). The assessment and analysis of handedness: the Edinburgh inventory. Neuropsychologia 9, 97-113.
33. Beck, A.T., Rial, W.Y., and Rickels, K. (1974). Short form of depression inventory: cross-validation. Psychol Rep 34, 1184-1186.
34. Hoddes, E., Zarcone, V., Smythe, H., Phillips, R., and Dement, W.C. (1973). Quantification of sleepiness: a new approach. Psychophysiology 10, 431-436.
35. Awiszus, F.B., J.J. (2011). TMS motor threshold assessment tool (MTAT 2.0). Brain Stimulation Laboratory. Medical University of South Carolina, USA.
36. King, B.R., Saucier, P., Albouy, G., Fogel, S.M., Rumpf, J.J., Klann, J., Buccino, G., Binkofski, F., Classen, J., Karni, A., et al. (2017). Cerebral Activation During Initial Motor Learning Forecasts Subsequent Sleep-Facilitated Memory Consolidation in Older Adults. Cereb Cortex 27, 1588-1601.
37. Rumpf, J.J., Wegscheider, M., Hinselmann, K., Fricke, C., King, B.R., Weise, D., Klann, J., Binkofski, F., Buccino, G., Karni, A., et al. (2017). Enhancement of motor consolidation by post-training transcranial direct current stimulation in older people. Neurobiol Aging 49, 1-8.
38. Janacsek, K., Shattuck, K.F., Tagarelli, K.M., Lum, J.A.G., Turkeltaub, P.E., and Ullman, M.T. (2020). Sequence learning in the human brain: A functional neuroanatomical meta-analysis of serial reaction time studies. Neuroimage 207, 116387.
39. Chen, R., Classen, J., Gerloff, C., Celnik, P., Wassermann, E.M., Hallett, M., and Cohen, L.G. (1997). Depression of motor cortex excitability by low-frequency transcranial magnetic stimulation. Neurology 48, 1398-1403.
40. Muellbacher, W., Ziemann, U., Boroojerdi, B., and Hallett, M. (2000). Effects of low-frequency transcranial magnetic stimulation on motor excitability and basic motor behavior. Clin Neurophysiol 111, 1002-1007.
41. Maeda, F., Keenan, J.P., Tormos, J.M., Topka, H., and Pascual-Leone, A. (2000). Modulation of corticospinal excitability by repetitive transcranial magnetic stimulation. Clin Neurophysiol 111, 800-805.
42. Rizzo, V., Siebner, H.R., Modugno, N., Pesenti, A., Munchau, A., Gerschlager, W., Webb, R.M., and Rothwell, J.C. (2004). Shaping the excitability of human motor cortex with premotor rTMS. J Physiol 554, 483-495.
43. Tecchio, F., Zappasodi, F., Assenza, G., Tombini, M., Vollaro, S., Barbati, G., and Rossini, P.M. (2010). Anodal transcranial direct current stimulation enhances procedural consolidation. J Neurophysiol 104, 1134-1140.
44. Krause, V., Meier, A., Dinkelbach, L., and Pollok, B. (2016). Beta Band Transcranial Alternating (tACS) and Direct Current Stimulation (tDCS) Applied After Initial Learning Facilitate Retrieval of a Motor Sequence. Front Behav Neurosci 10, 4.
45. King, B.R., Rumpf, J.J., Heise, K.F., Veldman, M.P., Peeters, R., Doyon, J., Classen, J., Albouy, G., and Swinnen, S.P. (2020). Lateralized effects of post-learning transcranial direct current stimulation on motor memory consolidation in older adults: An fMRI investigation. Neuroimage 223, 117323.
46. Chen, J., McCulloch, A., Kim, H., Kim, T., Rhee, J., Verwey, W.B., Buchanan, J.J., and Wright, D.L. (2020). Application of anodal tDCS at primary motor cortex immediately after practice of a motor sequence does not improve offline gain. Exp Brain Res 238, 29-37.